KR920015104A - evaporator - Google Patents

Abstract

No content

Description

evaporator

Since this is an open matter, no full text was included.

1 is a schematic diagram illustrating the operation of an evaporator according to the invention, FIG. 2 is a plan view of the evaporator according to the invention, and FIG. 3 is a side view of the evaporator according to the invention.

Claims (20)

An inlet for introducing evaporated refrigerant; An outlet for removing the refrigerant after evaporation; An inlet passage having a predetermined length and connected to the inlet for flowing refrigerant from the inlet; Evaporating means for heat exchange between a refrigerant inside the refrigerant means connected to the inlet passage for evaporating the refrigerant and a fluid outside the evaporation means; Pressure reducing means for throttling the flow of the refrigerant to the evaporation means to reduce the pressure of the refrigerant flowing to the evaporation means; An outlet passage having a crystal length connected to the outlet for flowing the refrigerant while in a mixed gas-liquid state from the evaporation means; First heat exchange means arranged in the inlet passage to cool the refrigerant to obtain a liquid state before the refrigerant enters the pressure reducing means; An evaporator suitable for use in a cooling cycle of a refrigerant comprising: second heat exchange means arranged in an outlet passage to heat the refrigerant in a superheated state in a mixed gas-liquid state. The evaporator of claim 1 wherein the first and second heat exchange means are arranged such that heat exchange takes place between the refrigerant in the inlet passage and the refrigerant in the outlet passage. 2. The refrigerant cycle according to claim 1, wherein the first heat exchange means is configured so that cooling of the refrigerant in the first heat exchange means and heating of the refrigerant in the second heat exchange means occur independently. Suitable for evaporator. An inlet for introducing evaporated refrigerant; An outlet for removing the refrigerant after evaporation; An inlet passage having a predetermined length and connected to the inlet for flowing refrigerant from the inlet; Evaporating means for heat exchange between a refrigerant inside the refrigerant means connected to the inlet passage for evaporating the refrigerant and a fluid outside the evaporation means; Pressure reducing means for throttling the flow of the refrigerant to the evaporation means to reduce the pressure of the refrigerant flowing to the evaporation means; An outlet passage having a predetermined length connected to the outlet and allowing the refrigerant to flow while in the mixed gas-liquid state from the evaporation means; The refrigerant in the outlet passage is arranged in close proximity to each other to be heated by the refrigerant in the inlet passage so that the refrigerant in the outlet passage and the inlet and outlet passages, etc. for use in the refrigeration cycle of the refrigerant, characterized in that Fit for evaporator. 5. The apparatus according to claim 4, wherein said evaporation means constitutes a plurality of stacked plates, each said plate having a first tube protrusion and a second tube protrusion and a reset and each adjacent pair of said plates being first and second. The inlet tank is formed inside the first protrusion and the outlet tank is formed inside the second protrusion so that the tube protrusion and the reset are faced inward so that a plurality of evaporation passages connect the reset and inlet tanks to the outlet tank. And an outside air passing between adjacent pairs of plates, the evaporator being suitable for use in a refrigeration cycle of refrigerant. 6. The evaporator of claim 5 wherein the evaporation means comprises a plurality of fins arranged between adjacent pairs of plates such that the outside air flow is in contact with the fins. 6. The evaporator of claim 5 wherein the evaporation means comprises a corrugated pipe comprising a plurality of parallel and curved portions connecting adjacent parallel portions. An inlet for introducing evaporated refrigerant; An outlet for removing the refrigerant after evaporation; An inlet passage having a predetermined length and connected to the inlet for flowing refrigerant from the inlet; A plurality of evaporation passages connected to the inlet passage to obtain heat exchange between the refrigerant inside the evaporation passage and the refrigerant inside the evaporation passage and thus evaporate the refrigerant; Pressure reducing means arranged between the inlet passage and the evaporation passage for throttling the refrigerant flow between the inlet passage and the evaporation passage to reduce the pressure of the refrigerant in the evaporation passage; An outlet passage having a predetermined length and connected to the outlet for providing a flow of refrigerant in a gas-liquid state mixed from the evaporation passage; An inlet and outlet passage in which the outlet passage is heated by the refrigerant in the inlet passage so that the refrigerant is superheated in the inlet passage; Evaporator suitable for use in the cooling cycle of the refrigerant comprising a. 9. The evaporator of claim 8, wherein the pressure reducing means comprises an orifice arranged upstream of each evaporation passage. 9. The evaporator of claim 8, wherein the pressure reducing means comprises a plurality of orifices arranged in respective evaporation passages. An outlet for introducing evaporated refrigerant; An outlet for removing the refrigerant after evaporation; An inlet passage having a predetermined length and connected to the inlet for flowing refrigerant from the inlet; Evaporation means connected to an inlet passage connected to an inlet passage to exchange heat between an oil system outside the evaporation means for evaporating the refrigerant and the refrigerant inside the evaporation means; An inlet passage for reducing the pressure of the refrigerant flowing through the evaporation means for providing the number of changes in the direction of the refrigerant flow; An outlet passage having a predetermined length connected to the outlet for flowing the refrigerant during the mixed gas-liquid state from the evaporation means; The refrigerant in the outlet passage is arranged in close proximity to each other in a manner that is heated by the refrigerant in the inlet passage so that the refrigerant in the outflow passage including the inlet and the outlet passage in the corrugated portion of the superheat evaporation state Evaporator suitable for use in cooling cycles. An inlet for introducing the evaporated refrigerant and an outlet for removing the refrigerant after evaporation; An inlet passage located downstream of the expansion valve to receive refrigerant from the expansion valve; An inlet passage having a length of a filter connected to the inlet to allow refrigerant to flow from the inlet; Evaporation means connected to the inlet passage and connected to the inlet passage for obtaining heat exchange between the refrigerant inside the evaporation means and the fluid to evaporate the refrigerant; Pressure reducing means arranged between the inlet passage and the evaporation means for throttling the flow of the refrigerant from the inlet to the passage adjacent to the evaporation passage to reduce the pressure of the refrigerant flowing in the steam means; An outlet passage having a predetermined length connected to the outlet and allowing the refrigerant to flow in the gas-liquid state mixed in the evaporation passage; The refrigerant in the outlet passage is arranged in close proximity to each other to be heated by the refrigerant in the inlet passage so that the refrigerant in the outlet passage includes an inlet and an outlet passage in which the superheated vapor state is used for a refrigeration cycle having an expansion valve. Suitable evaporator. An inlet for introducing evaporated refrigerant; An outlet for removing the refrigerant after evaporation; An inlet located upstream of the expansion valve to receive the refrigerant before entering the expansion valve; An inlet passage having a predetermined length and connected to the inlet to allow the refrigerant to flow from the inlet; An evaporation means connected to an inlet passage via an expansion valve to obtain a heat exchange between the refrigerant from the expansion valve and the fluid outside the evaporation means to evaporate the refrigerant, wherein the refrigerant in the evaporation passage is in a mixed gas-liquid state; An outlet passage having a predetermined length connected to the outlet and allowing the refrigerant to flow from the evaporation means; The refrigerant in the outlet passage is heated by the refrigerant in the inlet passage so that they are arranged in close proximity to each other so that the refrigerant is overheated evaporation of the outlet passage for use in a refrigeration cycle having an expansion valve comprising an inlet and an outlet passage. Suitable for evaporator. Recycle line of refrigerant; A compressor arranged on a recirculation line for compressing the refrigerant; A condenser arranged on a circulation line downstream of the compressor to condense a gaseous refrigerant and having a high pressure and a high temperature from the compressor; An expansion valve arranged in a recirculation line downstream of the condenser to receive the refrigerant in an adiabatic expansion process; An evaporator arranged in a recirculation line downstream of the condenser to expand and evaporate the refrigerant having a reduced pressure; And a heat exchanger for obtaining heat exchange of the refrigerant before and after evaporation in the gas-liquid state and before being fully saturated. An inlet for introducing the evaporated refrigerant; An outlet for removing the refrigerant after evaporation; Heat exchange means for flowing a refrigerant from an inlet with a predetermined length; Evaporation means for evaporating the refrigerant by obtaining a heat exchange between the refrigerant from the inlet passage and the fluid outside the evaporation means; Pressure reducing means positioned between the inlet passage and the evaporation means to throttle the flow of the refrigerant from the inlet passage to the evaporation means to reduce the pressure of the refrigerant flowing through the evaporation means; Heat exchange means for flowing a refrigerant from the evaporation passage having a plurality of outlet passages having a predetermined length; An evaporator suitable for use in a cooling cycle of a refrigerant comprising an inlet, an outlet passage, and the like, wherein the refrigerant in the outlet passage is brought into superheated vapor state of the outlet passage by the refrigerant in the inlet passage. 16. The apparatus of claim 15, wherein said heat exchange means comprises a plurality of loading plates, each said plate having first and second portions projecting outwardly and third and fourth portions projecting outwardly. The third and fourth portions form the first, second, third and fourth holes, and have corrugations in the area of each plate other than the first, second, third and fourth protrusions, and the adjacent plates face each other in consideration. The inlet passage is formed between the plates facing the corrugated portion, the outlet passage is formed between adjacent plates opposite the inlet passage, the first and second holes of the plate communicate with the inlet passage, and the third and fourth holes of the plate An evaporator suitable for use in a cooling cycle of a refrigerant characterized by communicating with an outlet passage. A joint block having an inlet for introducing the evaporated refrigerant and an outlet for removing the refrigerant after evaporation; A heat exchanger having a predetermined length and having at least one passage connected to the inlet to allow the refrigerant to flow from the inlet; The pressure of the refrigerant flowing in the evaporation means connected to the inlet passage and arranged between the refrigerant from the inlet passage and the evaporation passage for evaporating the refrigerant by obtaining heat exchange between the fluid outside the evaporation means. An evaporator having one or more orifices to reduce the pressure; Said heat exchange portion having at least one length and connected to the outlet and having at least one outlet passage for flowing the refrigerant while in the gas-liquid state mixed from the evaporator means; It is known to be used for the cooling cycle of the refrigerant comprising an inlet and outlet passages such that the refrigerant in the outlet passage is closely arranged with each other so that the refrigerant is heated by the refrigerant in the inlet passage so that the refrigerant is in a superheated state of the outlet passage. Fit for evaporator. 18. The evaporator of claim 17 wherein said joint block, said heat exchanger and evaporator are connected together to form an assembly evaporator. 18. The apparatus of claim 17, further comprising: a second evaporator having at least one evaporation passage connected to the inlet passage for obtaining heat exchange between the refrigerant from the inlet passage and the fluid outside the evaporation means and evaporating the refrigerant; One or more orifices arranged to throttle the flow of the refrigerant from the inlet passage to the evaporation means to reduce the pressure of the refrigerant flowing in the evaporation means and connected to the outlet with a predetermined length to bring the refrigerant into the mixed gas-liquid state from the evaporation means. Cooling of the refrigerant further comprising at least one inlet passage and the outlet passage for flowing the refrigerant in the outlet passage is arranged in close proximity to each other to be heated by the refrigerant in the inlet passage so that the refrigerant is in the superheated state of the outlet passage Evaporator suitable for use in cycles. 20. The evaporator of claim 19 wherein the first and second evaporators are arranged on opposite sides of the heat exchanger. ※ Note: This is to be disclosed by the original application.